DE10202427A1 - Glass used for optical applications contains a specified amount of lithium oxide and has specified refractive index and Abbe number - Google Patents

Abstract

Glass obtained from an inductively heated glass melt contains 0.05-2.0 wt.% Li2O and has a refractive index of 1.55-1.79 and/or an Abbe number of 25-42. An Independent claim is also included for a process for the production of the glass. Preferred Features: The glass contains (in wt.%): 29-56 SiO2, 30-67 PbO, 0.25-2.0 Li2O, 0-15 Na2O, 0-15 K2O, 0.25-25 Li2O + Na2O + K2O, 0-0.3 ZnO and/or Al2O3, and 0-0.25 As2O3. The glass preferably contains 0-7 Na2O and 0-7 K2O. The glass especially contains (in wt.%): 32-48 SiO2, 43-62 PbO, 0-6 Li2O, 0-6 Na2O, 0.25-9 K2O, 0.25-25 Li2O + Na2O + K2O.

Description

The invention relates to a glass, which consists of a direct inductively heated glass melt is obtained and a Process for the manufacture of glasses by inductive Heating according to the features of claims 1 and 11, above the invention also relates to glasses or optical glasses according to the features of claims 1 and 17.

Glasses and in particular optical glasses are known, the refractive indices n _{d of which are} between 1.55 and 1.79 and the Abbe numbers ν _d of 25 to 42. In general, however, these glasses do not always meet the quality requirements of manufacturers of optical instruments and products. The reason for this is in particular due to impurities resulting from the respective technological manufacturing process. In this respect, known glasses for optical applications contain an increased amount of trace impurities, in particular platinum and polyvalent ions, which have a glass-coloring effect.

The melting devices usually used are are so-called platinum aggregates, in which under usual melting conditions optical light flint, flint and Heavy flint glasses are melted.

In principle, of course, there would be the possibility of producing glasses of the required high purity in so-called silica glass apparatus. The disadvantage here, however, is that the service life of the silica glass apparatus is very limited compared to the mostly highly corrosive glass melts. The production of glasses with such apparatus is therefore uneconomical. It should also be pointed out that when melting glass in the pebble apparatus, larger amounts of As ₂ O _{3 are used} for the refining, since the melting temperature has to be kept particularly low to minimize corrosion during glass production. However, As ₂ O ₃ has the disadvantage that it is very polluting.

In this context, particular attention should be paid to the documents JP-A-9150138, JP-A-89270536 and WO 9856724 refer to the Disclose glasses which are generic to those after Invention correspond.

With reference to WO 9856724, however, it should be noted that the glasses to be removed therefrom do not contain Li ₂ O. However, this means that the glasses presented there cannot be obtained from an inductively heated melt, since the conductivity of the glasses is not sufficient to be able to couple the melt inductively to the required extent.

In contrast to this, a Li ₂ O content of well over 2% is used in the exemplary embodiment according to JP-A-89270536. With amounts of more than 2% of Li ₂ O, however, the optical position of the glasses changes increasingly. Furthermore, their chemical resistance is deteriorated. The deteriorated optical properties can then, if at all, only be compensated for by the use of expensive, high-melting or yellow-discolored components.

The glasses disclosed in JP-A-3050138 have the particular disadvantage that they contain a comparatively high proportion of As ₂ O ₃ of at least 0.28%. However, as already described, this proportion should be as small as possible due to its environmental impact.

Against the background of the state of the Technology is therefore the object of the invention in particular to avoid the recorded disadvantages and Provide glasses with high purity that are inexpensive and can be manufactured efficiently.

Most surprisingly, this task has already been solved through a glass according to the features of claim 1. Furthermore a method is defined in claim 11, according to which the Glasses according to the invention can be produced. About that in addition, claims 13 and 17 are specific glasses specified according to the invention.

Advantageous further developments can be found in each assigned subclaims.

The direct coupling of energy into the invention In particular, the melt or the melt material is said to be direct inductive coupling of energy, in which without a crucible that absorbs the energy and to the melting material transfers.

According to the invention, a glass is specified, in particular for optical applications, which is obtained from a directly inductively heated glass melt and contains a defined proportion of Li ₂ O of 0.25 to 2.0 (in percent by weight on an oxide basis) and / or which has a refractive index from 1.55 to 1.79 and / or an Abbe number from 25 to 42.

The glasses according to the invention therefore contain for the first time a specifically selected proportion of Li ₂ O (lithium I-oxide). It should be emphasized at this point that it was previously assumed that the optical position of z. B. light flint, flint and heavy flint glass compositions, the relatively expensive component Li is not needed at all and it would not offer any advantages in the conventional melting process.

Now, however, within the scope of the invention with special Advantages highlighted precisely because of the targeted Adding lithium i-oxide to the conductivity of glasses in the Disproportionately more suitable than other alkalis Way can be increased, but the addition - at application according to the invention - the optical position of the glasses influenced only very slightly. For example, the Value of electrical conductivity by adding Lithium I-oxide in the range of the lower melting temperature of 1200 to 1300 ° C to about three times the initial value of the originally brought lithium-free glass. This leads to the very positive result that the so with glasses equipped with increased conductivity direct inductive heating of the melt simple, manufactured inexpensively and with high optical quality can be.

For the melting technology of direct inductive heating, z. B. in a so-called skull crucible, one uses the principle the absorption of electromagnetic fields in one conductive material. The energy turns into heat converted. With this technology it is possible To heat glass melts yourself. By the solidification of the The melt forms on the cooled crucible wall a crucible made of its own material. So that's one Contamination of the melt due to corrosion of the Wall contact surface, such as. B. in platinum units, locked out.

Another advantage of this technology is the relatively high variability of the melting temperatures due to the independence of certain crucible materials. By changing the temperatures in the melting process (melting phases of elevated temperature), the redox ratios of polyvalent ions contained as trace impurities can be effectively shifted to more favorable ranges. This is particularly important for the main impurity iron, in which the Fe ³⁺ / Fe ²⁺ redox ratio can be shifted far to the side of the normally less disturbing Fe ²⁺ . This leads to a clear discoloration of the glasses and to a further improvement in transmission in parts of the spectrum of interest.

Likewise, the refining potential of the used Refining agent by further shifting to the lower Value level with simultaneous oxygen release better exploited.

The phases of increased melting temperatures also serve because of the then lower viscosities the better physical refining of the melt, at the same or even smaller amounts of refining agents than previously customary and also lead to better homogenization of the Melt.

Such a skull crucible is, for example, DE-C-199 39 772 refer to. Their content, due to the importance of Melting technology of inductive heating for the present invention, hereby incorporated by reference Registration is included.

In this context, as already mentioned, it has been found in the context of the invention that the desired meltability with direct inductive heating of the melt is already possible from a Li ₂ O content of 0.25. The only slight addition of Li ₂ O of only up to 2% does not only lead to the positive result that the glass in the melt, e.g. B. in a skull crucible, can be continuously coupled to a radio frequency, but also to the fact that the possibility has been created in a highly advantageous way according to the invention that the optical properties of potential starting glasses are only slightly insofar as the targeted and defined addition of only a little Li ₂ O. be changed so that these changes can be easily compensated for. If, for example, amounts of more than 2% of Li ₂ O were used, this would have severe negative consequences for the optical position of such glasses. In addition, the tendency to crystallize would increase sharply and the batch price would rise sharply due to the high price for Li ₂ O.

As a consequence, this means that the original compositions of conventional light flint glasses, flint glasses and heavy flint glasses, which, as already mentioned, usually do not contain Li ₂ O, only have to be changed to the extent that inductive meltability of the glasses is ensured, the optical data and secondary Properties such as transformation temperature, chemical resistance, machinability and crystallization behavior remain largely unchanged.

In a highly advantageous development of the subject matter of the invention, the inventors found that the glasses according to the invention essentially have optimal properties if they have the following compositions in percent by weight on an oxide basis:
SiO ₂ : 29 to 56%; PbO: 30 to 67%; Li ₂ O: ≥ 0.25 to 2%; Na ₂ O: 0 to 15%; K ₂ O: 0 to 15%; where Σ (Na ₂ O + K ₂ O + Li ₂ O) 0.25 to 25%; ZnO: 0 to 0.3%; Al ₂ O ₃ : 0 to ≤ 0.3%; As ₂ O ₃ : 0 to ≤ 0.25.

Glasses according to the previous ones Compositional areas meet the requirement above all after reaching the desired optical properties simultaneous meltability by means of inductive heating in a skull crucible, with the possibility of melting at higher temperatures, to achieve that for optical glasses necessary glass quality.

It should be noted that, according to the invention, significantly less arsenic is required than in the glasses melted using conventional melting technology. According to a particularly preferred embodiment variant, the proportion of As ₂ O _{3 is} even less than or equal to 0.2% (weight percent on an oxide basis).

As stated, the glass according to the invention contains a proportion of silicon dioxide (SiO ₂ ) of 29 to 56 percent by weight on an oxide basis. In a particularly preferred embodiment, the glass according to the invention contains 33 to 48% 8102. On the basis of these weight percentages, the glasses according to the invention have an essentially optimized crystallization stability and a very good acid resistance. At lower values, the good crystallization stability and good acid resistance are lost, at higher values, the meltability decreases. In particular, if alkali oxides have to be added in large amounts to improve the meltability, a higher SiO ₂ content is no longer useful for improving the acid resistance.

According to a further advantageous production variant of the glass according to the invention, this comprises a percentage by weight based on oxide of Na ₂ O from 0 to 7% and a percentage of K ₂ O from 0 to 7%. Furthermore, the glass preferably contains SiO ₂ from 29 to 56%; PbO from 30 to 65%; Li ₂ O from 0.25 to 2.0%; Σ (Li ₂ O + Na ₂ O + K ₂ O) from 0.25 to 25%; ZnO from 0 to 0.3%; Al ₂ O ₃ from 0 to 0.3% and As ₂ O ₃ from 0 to 0.25%. Taking into account the composition ranges mentioned, glasses according to the invention can advantageously be obtained, in particular optical glasses which have a refractive index of 1.57 to 1.76 and / or an Abbe number of 25 to 37.

Another embodiment variant of the invention relates to percentage ranges in percent by weight based on oxide with respect to SiO ₂ , PbO, Na ₂ O and K ₂ O, which as a result lead to optical glasses which have a refractive index of 1.60 to 1.73 and / or Abbe number from 27 to 37. SiO ₂ comprises a range from 32 to 48%, PbO one from 43 to 62%, Na ₂ O one from 0 to 6%, K ₂ O one from 0 to 6% and the sum of the proportions Li ₂ O, Na ₂ O and K ₂ O have a total of 0.25 to 9%. The proportion ranges for Li ₂ O, ZnO, Al ₂ O ₃ and As ₂ O ₃ correspond to those from the previous exemplary embodiments.

Another advantageous further development of the subject matter of the invention also consists in the subsequent production variant of glasses according to the invention. Here, in weight percent based on oxide, SiO _{2 has} a percentage range from 44 to 48%, Li ₂ O from 0.3 to 2.0%, Na ₂ O from 0 to 8%, K ₂ O from 0 to 8% and the sum of the proportions of Li ₂ O, Na ₂ O and K ₂ O should be limited to a range from 0.3 to 12%. In addition, PbO fractions of 30 to 46% are preferably provided and the ZnO fractions in a range between 0 and 0.3% and that of Al ₂ O ₃ in a range between 0 and 0.3% and that of As ₂ O ₃ would be kept in a range from 0 to 0.25%. If glasses according to the invention are produced with fractions which lie within the specified ranges, these glasses can most advantageously achieve a refractive index between 1.6 and 1.65 and an Abbe value of 33 to 37.

In connection with the embodiment variants mentioned, the invention also proposes glasses in which the ratio of K ₂ O and the sum of the proportions of Na ₂ O and Li ₂ O is preferably less than or equal to 2. It is advantageously ensured by such a ratio that the glasses can be essentially optimally coupled in during inductive heating. If a value greater than 2 is selected, as is sometimes the case in the prior art, the inductive coupling of the glasses deteriorates significantly and, if at all, it only succeeds at relatively high temperatures. Accordingly, such glasses can only be melted at very high temperatures.

The invention is also based on the knowledge that it is highly advantageous if the sum of the proportions in percent by weight on an oxide basis of Na ₂ O and K ₂ O is limited to a range between 7.4 and 25%. In principle, Na ₂ O and K ₂ O also contribute to the conductivity of the glass, but the conductivity of Li ₂ O is much greater than that of Na ₂ O and the latter is greater than that of K ₂ O, so that the required high conductivities, relatively large amounts of Na ₂ O and / or K ₂ O would have to be introduced into the glasses. In this context, reference is again made to the previous section, the ratio given there ensuring that the proportions of the more conductive materials sodium I-oxide and lithium I-oxide are significantly larger than those of potassium I-oxide.

Of course, there would in principle be the possibility of producing sufficient conductivity without Li ₂ O purely via the Na ₂ O or K ₂ O content. However, inductive coupling would then only be possible at relatively high temperatures. In addition, this would have further negative consequences because, due to the resulting increased alkali oxide evaporation, the constancy of composition and the stability of the coupling behavior can no longer be guaranteed. Furthermore, in this case the usable temperature range would be significantly smaller compared to the glasses according to the invention. In addition, the production of the glasses would become increasingly uneconomical by melting at higher temperatures and the chemical resistance would decrease with higher alkali oxide contents. Glasses which have different alkali oxide ratios and in particular those which shift the ratio to the disadvantage of lithium I-oxide regularly have significantly poorer properties with regard to expansion coefficients, transformation temperatures and acid resistance.

The glasses according to the invention mentioned above include further 30 to 65% (weight percent on an oxide basis) PbO. at the optical properties are not lower values to achieve more and the crystallization stability and Meltability is lost. At higher levels, the Acid resistance and transparency in the short-wave range worsens. Especially if also Alkaline oxides are present in larger quantities no higher PbO content to increase the refractive index relevant. According to a further preferred embodiment the glass contains 43 to 62% PbO.

According to a particularly advantageous embodiment variant of the Glass according to the invention contains the same one Lead oxide content of at least 50%. Based on that it is highly advantageous that the pure transmission a value of at least 0.95, measured at a Wavelength of 400 nm and a sample thickness of 25 mm having.

Furthermore, it was recognized according to the invention that when the Lead oxide content below 50% (weight percent on oxide basis) is limited, the pure transmission has a value of can assume at least 0.98. The latter also measured at a wavelength of 400 nm and a sample thickness of 25 mm.

Furthermore, the glass can contain up to 0.3% ZnO and / or Al ₂ O ₃ for fine adjustment of the optical position and other glass properties.

However, the invention does not only give glasses of the highest quality Quality, but also a process based on it the glasses can be made. This will start with a melting device for melting a batch of glass provided, the melting device for inductive heating of the glass batch.

The batch of glass is then poured into the melting device, with the addition of Li ₂ O to the batch of glass, the composition of the batch being adapted such that the batch of glass is transferred in a conductive, inductively heatable state in such a way that the glass obtained has a refractive index of 1 , 55 to 1.79 and / or an Abbe number of 25 to 42. In this way, for example, the re-development of glasses that were originally not inductively fusible is also advantageously possible.

The invention is described in detail below with the aid of a few examples. Example 1 Table 1 Redevelopment of an inductively non-meltable glass into an inductively meltable glass (in percent by weight)

Table 1 shows a so-called redevelopment of an originally non-inductively fusible glass into an inductively fusible glass. As can be seen there, the redesigned glass has a Li ₂ O content of 0.8% compared to the original glass composition. The addition of the lithium oxide was achieved in particular by reducing the lead oxide from 61.5% to 59.7% and by reducing the potassium I-oxide by 0.1 to 2.4% by weight and by increasing the proportion of silicon dioxide from 33. 9% balanced to 35.4%.

As can be seen in the lower part of the table with the physical data, the physical properties of the redesigned glasses could be kept essentially constant in comparison to the original composition. What is striking, however, is the significantly lower electrical resistance that was achieved by adding Li ₂ O to the redesigned glass. By reducing the specific electrical resistance from 15 Ωcm to 7 Ωcm at temperatures of 1200 ° C, it was possible to obtain the redesigned glass from an inductively heated melt.

During production and / or redevelopment, the following steps must be observed in particular: The raw materials for the oxides, preferably carbonates and nitrates, are weighed out, the refining agent, As ₂ O ₃ is added and then mixed well. The glass batch is melted in a high-frequency melting unit at approx. 1150 to 1650 ° C, then refined and homogenized well. The casting temperature is 850 to 1150 ° C.

A production example for a glass according to the invention can be found in Table 2 below. Column 2 shows the percentages by weight and column 4 shows the weight in kilograms of the individual glass portions added. Example 2 Table 2 Melting example for 100 kg of calculated glass

The properties of the glass thus obtained are given in Table 3 below under No. 6. Table 3 Melting Examples 1 to 6 (in percent by weight)

Table 3 Melting Examples 7 to 8 (in percent by weight)

Table 3 contains a total of eleven exemplary embodiments No. 1 to 11 in the composition ranges according to the invention. It in addition to the optical properties are exemplary specified several physico-chemical properties.

The abbreviation n _{d stands} for the refractive index measured using the Fraunhofer line d at λ = 587.5618 nm. As usual, the Greek letter ν _d corresponds to the so-called Abbe number for the corresponding Fraunhofer lines. P _{g, F} is the relative partial dispersion measured on the Fraunhofer lines g and F and ΔP _{g, F.} corresponds to the anomaly of this partial dispersion. In the table, the density was given in grams / cm ³ and the coefficient of thermal expansion α in units of 10 ^-6 × K ^-1 and the transformation temperature Tg in degrees Celsius (° C), as well as the pure transmission τ ₁ at λ = 400 nm and a sample thickness of 25 mm.

From Table 3 it is clear that it is according to the invention has succeeded in producing glasses that Pure transmittance of e.g. 98.2, 99.9 and 99.4% exhibit. For this, in particular the melting examples No. 5, 8 and 10 of Table 3. This was after the Invention proved most advantageously that optical glasses with high quality especially light flint, flint and Heavy flint glasses of very high purity, and therefore with a lot good optical transmission values inductive heating in a skull crucible can, otherwise with conventional melting techniques are not reachable. Take note of the specified Also value that the transmittance is not linear, but logarithmic from the concentration of the absorbing contaminants, it becomes clear that through the inductive melting in the skull crucible Concentration of impurities by orders of magnitude can be improved.

Furthermore, it should be pointed out again that the refining agent content, in particular that of As ₂ O ₃ , is in particular significantly lower than is usually the case. Table 3 shows a maximum value of 0.2 percent by weight for melting examples Nos. 1, 5, 8, 9 and 10.

Claims (17)

1. Glass, in particular for optical applications, which is obtained from an inductively heated glass melt and contains a proportion of Li ₂ O of 0.25 to 2.0 (in percent by weight on an oxide basis) and / or which has a refractive index of 1.55 to 1.79 and / or an Abbe number of 25 to 42. 2. Glass according to claim 1 comprising the following proportions (in weight percent on an oxide basis):
SiO ₂ 29 to 56 PbO 30 to 67 Li ₂ O 0.25 to 2.0 Na ₂ O 0 to 15 K ₂ O 0 to 15 Σ (Li ₂ O + Na ₂ O + K ₂ O) 0.25 to 25 and / or ZnO and / or Al ₂ O ₃ with proportions of 0 to 0.3% and / or As ₂ O ₃ with a proportion of 0 to 0.25%. 3. Glass according to claim 1 or 2 comprising the following proportions (in weight percent on an oxide basis) of Na ₂ O and K ₂ O:
Na ₂ O 0 to 7 K ₂ O 0 to 7 the glass having a refractive index from 1.57 to 1.76 and / or an Abbe number from 25 to 37. 4. Glass according to one of the preceding claims comprising the following proportions (in weight percent on an oxide basis) of SiO ₂ , PbO, Na ₂ O and K ₂ O:
SiO ₂ 32 to 48 PbO 43 to 62 Na ₂ O 0 to 6 K ₂ O 0 to 6 Σ (Li ₂ O + Na ₂ O + K ₂ O) 0.25 to 9 the glass having a refractive index of 1.60 to 1.73 and / or an Abbe number of 27 to 37. 5. Glass according to one of the preceding claims comprising the following proportions (in weight percent on an oxide basis) of SiO ₂ , Li ₂ O, Na ₂ O and K ₂ O:
SiO ₂ 44 to 48 Li ₂ O 0.3 to 2.0 Na ₂ C 0 to 8 K ₂ O 0 to 8 Σ (Li ₂ O + Na ₂ O + K ₂ O) 0.3 to 12 the glass having a refractive index of 1.60 to 1.65 and / or an Abbe number of 33 to 37. 6. Glass according to one of the preceding claims comprising the following composition:
K ₂ O: (Na ₂ O + Li ₂ O) ≤ 2. 7. Glass according to one of the preceding claims comprising the following composition:
Σ (Na ₂ O + K ₂ O) = 7.4 to 25% (in weight percent on an oxide basis). 8. Glass according to one of the preceding claims comprising the following proportions of refining agent As ₂ O ₃ :
0.05% to 0.25% (in weight percent based on oxide). 9. Glass according to one of the preceding claims, wherein the glass has a PbO content of at least 50% and a pure transmission of at least 0.95, measured at a wavelength of 400 nm (nanometers) and a sample thickness of 25 mm (millimeters) and / or has a content of Li ₂ O of 0.25 to 2.0% by weight on an oxide basis). 10. Glass according to one of the preceding claims, wherein the Glass has a PbO content of less than 50% and one Pure transmission of at least 0.98, measured at a Wavelength of 400 nm (nanometer) and a sample thickness of 25 mm (millimeters). 11. A method for producing glasses, in particular for producing glasses according to one of the preceding claims, comprising the following steps: a) providing a melting device for melting a batch of glass, the melting device comprising a device for inductively heating the batch of glass, b) pouring the batch of glass into the melting device to obtain the glass, whereby with a defined addition of Li ₂ O into the glass batch, the composition of the batch is adjusted such that the glass batch is converted into a conductive inductively heatable state in such a way that the glass obtained has a refractive index of 1.55 to 1.79 and / or has an Abbe number of 25 to 42. 12. The method according to claim 11, wherein an amount of Li ₂ O is added to the glass batch such that the glass has a Li ₂ O content of 0.22 to 2.0. 13. Optical glass, in particular a composition according to containing one of claims 1 to 10 and / or in particular produced by a method according to a of claims 11 to 12, wherein the glass by a inductive heating is obtained and a Pure transmission of at least 0.95 included. 14. The optical glass of claim 13, wherein the glass is a PbO content of at least 50%. 15. An optical glass according to claim 13, wherein the glass is a PbO content of less than 50% and one Pure transmission of at least 0.98 included. 16. Optical glass according to one of claims 13 to 15, wherein the glass has a Li ₂ O content of 0.22 to 2.0. 17. Glass, in particular containing and / or in particular a composition according to one of claims 1 to 10 produced by a method according to one of claims 11 to 12, wherein the glass has the following composition: K ₂ O: (Na ₂ O + Li ₂ O ) ≤ 2.